US11511239B2ActiveUtilityA1

Heated flash-boiling doser with integrated helix

42
Assignee: FAURECIA EMISSIONS CONTROL TECHNOLOGIES USA LLCPriority: Apr 29, 2020Filed: Apr 29, 2020Granted: Nov 29, 2022
Est. expiryApr 29, 2040(~13.8 yrs left)· nominal 20-yr term from priority
B01F 25/314F01N 2610/02Y02A50/20B01F 25/313F01N 2590/08F01N 3/2066Y02T10/12B01F 23/2132B01F 23/711F01N 2240/02B01F 23/211F01N 2610/14
42
PatentIndex Score
0
Cited by
88
References
12
Claims

Abstract

An exhaust aftertreatment system for use with over-the-road vehicle is disclosed. The exhaust aftertreatment system includes a reducing agent mixer with a mixing can and a flash-boil doser configured to inject heated and pressurized reducing agent into the mixing can for distribution throughout exhaust gases passed through the mixing can.

Claims

exact text as granted — not AI-modified
The invention claimed is: 
     
       1. A flash-boil doser adapted for use in an exhaust aftertreatment system to inject a reducing agent into an exhaust passageway of the exhaust aftertreatment system, the flash-boil doser comprising
 a doser body including a housing and a heat exchanger assembly, the heat exchanger assembly arranged in the housing and configured to heat the reducing agent thereby increasing a pressure within the heat exchanger assembly to drive injection of the reducing agent into the exhaust passageway, 
 a doser inlet coupled to the doser body that defines an inlet passageway that opens into the heat exchanger assembly to admit reducing agent from an associated reducing agent tank, and 
 a doser outlet coupled to the doser body that defines an outlet passageway that opens from the heat exchanger assembly into the exhaust passageway, the doser outlet spaced apart axially from the doser inlet relative to a doser axis of the flash-boil doser, 
 wherein the heat exchanger assembly includes (i) an outer sleeve shaped to define a spiral channel that wraps around the doser axis and opens toward the doser axis, (ii) an inner sleeve arranged in the outer sleeve to close the spiral channel to form a helical passageway between the outer sleeve and the inner sleeve that is in fluid communication with the inlet and outlet passageways, and (iii) at least one heater arranged around an outer surface of the outer sleeve and configured to conductively heat the outer sleeve to heat the reducing agent in the helical passageway, and 
 wherein the doser outlet includes a pressure-activated outlet valve that blocks or allows flow through the outlet passageway, the pressure-activated outlet valve configured to move from a normally-closed position to an open position when a predetermined pressure within the helical passageway is reached to discharge the heated reducing agent from the helical passageway through the outlet passageway and into the exhaust passageway for mixing with the exhaust gases therein during use of the flash-boil doser in the exhaust aftertreatment system. 
 
     
     
       2. The doser of  claim 1 , wherein the inner sleeve is interference fit with the outer sleeve. 
     
     
       3. The doser of  claim 1 , wherein the heat exchanger assembly further includes a first guide plate coupled to a first end of the outer sleeve to form a heat exchanger inlet that opens into the helical passageway and a second guide plate coupled to a second end of the outer sleeve to form a heat exchanger outlet that opens into the outlet passageway, the first and second guide plates are configured to block the reducing agent from flowing into an inner passageway that extends axially through the inner sleeve. 
     
     
       4. The doser of  claim 3 , wherein the heat exchanger assembly further includes an insulation layer arranged in the inner passageway of the inner sleeve. 
     
     
       5. The doser of  claim 1 , wherein the inner sleeve is shaped to include an inner passageway that extends axially through the inner sleeve and is sized to receive a portion of the pressure-activated outlet valve such that the heat exchanger assembly is arranged around a portion of the pressure-activated outlet valve. 
     
     
       6. The doser of  claim 5 , wherein the heat exchanger assembly further includes an insulation layer arranged in the inner passageway of the inner sleeve around the portion of the pressure-activated outlet valve. 
     
     
       7. A reducing agent mixer for use in an exhaust aftertreatment system for an over-the-road vehicle, the reducing agent mixer comprising
 a mixing can defining at least a portion of an exhaust passageway for receiving a flow of exhaust gases therein, and 
 a flash-boil doser mounted to the mixing can and configured to heat a reducing agent to drive the reducing agent to a predetermined pressure and to inject the reducing agent into the exhaust passageway of the mixing can, the flash-boil doser comprising
 a doser body including a housing and a heat exchanger assembly, the heat exchanger assembly arranged in the housing and configured to heat the reducing agent thereby increasing a pressure within the heat exchanger assembly to drive injection of the reducing agent into the exhaust passageway, 
 a doser inlet coupled to the doser body that defines an inlet passageway that opens into the heat exchanger assembly to admit reducing agent from an associated reducing agent tank, and 
 a doser outlet coupled to the doser body that defines an outlet passageway that opens from the heat exchanger assembly into the exhaust passageway, the doser outlet spaced apart axially from the doser inlet relative to a doser axis of the flash-boil doser, 
 
 wherein the heat exchanger assembly includes (i) an outer sleeve shaped to define a spiral channel that wraps around the doser axis and opens toward the doser axis, (ii) an inner sleeve arranged in the outer sleeve to close the spiral channel to form a helical passageway between the outer sleeve and the inner sleeve that is in fluid communication with the inlet and outlet passageways, and (iii) at least one heater arranged around an outer surface of the outer sleeve and configured to conductively heat the outer sleeve to heat the reducing agent in the helical passageway, and 
 wherein the doser outlet includes a pressure-activated outlet valve that blocks or allows flow through the outlet passageway, the pressure-activated outlet valve configured to move from a normally-closed position to an open position when the predetermined pressure within the helical passageway is reached to discharge the heated reducing agent from the helical passageway through the outlet passageway and into the exhaust passageway for mixing with the exhaust gases therein during use of the flash-boil doser in the exhaust aftertreatment system. 
 
     
     
       8. The reducing agent mixer of  claim 7 , wherein the inner sleeve is interference fit with the outer sleeve. 
     
     
       9. The reducing agent mixer of  claim 7 , wherein the heat exchanger assembly further includes a first guide plate coupled to a first end of the outer sleeve to form a heat exchanger inlet that opens in to the helical passageway and a second guide plate coupled to a second end of the outer sleeve to form a heat exchanger outlet that opens into the outlet passageway, the first and second guide plates are configured to block the reducing agent from flowing into an inner passageway that extends through the inner sleeve. 
     
     
       10. The reducing agent mixer of  claim 7 , wherein the inner sleeve is shaped to include an inner passageway that extends axially through the inner sleeve and is sized to receive a portion of the pressure-activated outlet valve such that the heat exchanger assembly is arranged around a portion of the pressure-activated outlet valve. 
     
     
       11. The reducing agent mixer of  claim 10 , wherein the heat exchanger assembly further includes an insulation layer arranged in the inner passageway of the inner sleeve around the portion of the pressure-activated outlet valve. 
     
     
       12. An over-the-road vehicle, the vehicle comprising
 an internal combustion engine configured to produce a flow of exhaust gases that are conducted through an exhaust passageway defined by an exhaust conduit, and 
 an exhaust aftertreatment system configured to treat the flow of exhaust gases, the system comprising
 a reducing agent tank formed to store a reducing agent therein, 
 a mixing can defining at least a portion of the exhaust passageway for receiving the flow of exhaust gases therein, and 
 a flash-boil doser mounted to the mixing can and configured to heat the reducing agent to drive the reducing agent to a predetermined pressure and to inject the reducing agent into the exhaust passageway of the mixing can, the flash-boil doser comprising
 a doser body including a housing and a heat exchanger assembly, the heat exchanger assembly arranged in the housing and configured to heat the reducing agent thereby increasing a pressure within the heat exchanger assembly to drive injection of the reducing agent into the exhaust passageway, 
 a doser inlet coupled to the doser body that defines an inlet passageway that opens into the heat exchanger assembly to admit reducing agent from the reducing agent tank, and 
 a doser outlet coupled to the doser body that defines an outlet passageway that opens from the heat exchanger assembly into the exhaust passageway, the doser outlet spaced apart axially from the doser inlet relative to a doser axis of the flash-boil doser, 
 wherein the heat exchanger assembly includes (i) an outer sleeve shaped to define a spiral channel that wraps around the doser axis and opens toward the doser axis, (ii) an inner sleeve arranged in the outer sleeve to close the spiral channel to form a helical passageway between the outer sleeve and the inner sleeve that is in fluid communication with the inlet and outlet passageways, and (iii) at least one heater arranged around an outer surface of the outer sleeve and configured to conductively heat the outer sleeve to heat the reducing agent in the helical passageway, and 
 
 wherein the doser outlet includes a pressure-activated outlet valve that blocks or allows flow through the outlet passageway, the pressure-activated outlet valve configured to move from a normally-closed position to an open position when a predetermined pressure within the helical passageway is reached to discharge the heated reducing agent from the helical passageway through the outlet passageway and into the exhaust passageway for mixing with the exhaust gases therein during use of the flash-boil doser in the exhaust aftertreatment system.

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